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Human biology Laboratory
Lecturer Maysam A Mezher
Cell division
CHROMOSOME STRUCTURE
1. During nuclear division, the DNA (as chromatin) in a Eukaryotic cell's nucleus is coiled into very tight compact structures called chromosomes. These are rod-shaped structures made of protein and DNA, which are visible (when stained) only during nuclear division.
2. The DNA in Eukaryotic cells is coiled tightly around proteins called histones, which help in the tight packing of DNA. During interphase, the DNA is not tightly coiled into chromosomes, but exists as chromatin.
3. When preparing for nuclear division, during the S phase of interphase, the chromosomes copy themselves (i.e. DNA replication occurs). Each half of the chromosome is now called a chromatid.
Note that there is still only one chromosome; it consists of two chromatids but has only one centromere. The function of this is to hold the two chromatids together until they separate during anaphase.
4. Chromosomes are simpler in Prokaryotes. Their DNA is in a single chromosome, and exists as a loop .
CHROMOSOME NUMBERS
1. Each human somatic (or body) cell contains two complete sets of chromosomes (one from each parent). This is the normal for Eukaryotes and is known as diploid (2n). For humans (only) this means our cells have 46 chromosomes.
2. Sex cells (gametes – eggs and sperm) have only one set of chromosomes (in humans, 23) and such cells are known as haploid (n). Each cell is unique, as it is produced by meiosis (though the ‘mother cells’ for the gametes are produced by mitosis, the final division is always meiotic).
3. Meiosis is necessary because most organisms reproduce sexually, and during fertilization, the gametes fuse and the number of chromosomes therefore doubles (sperm (n) + egg (n) = 2n), to produce the first cell of the next generation – the zygote (2n).
4. Chromosomes can be divided into two types. In humans, we have 22 pairs of autosomes, which are the same in every individual, and one pair of sex chromosomes (XX = female, XY = male).
CELL DIVISION PROKARYOTES
1. Prokaryotic cells divide by binary fission, in which the DNA replicates and then the cell divides in two. That’s all – no mitosis, no spindle, no nothing!
2- EUKARYOTES A cell typically goes through three phases during its life, beginning with growth before it can divide.
This is known as the cell cycle and consists of three phases:
A- Interphase
B- Mitosis (nuclear division, producing
2 identical nuclei)
C- Cytokinesis (cell division, producing
2 roughly equal cells)
A- INTERPHASE
1- This is the longest phase of the cell cycle and can last from a few hours to many years. It used to be known as the ‘resting phase’, which is completely misleading, as it is during this time of normal metabolic activity that the cell performs all its normal functions, beginning with growth and development.
2- Interphase can be divided into 3 stages:
I- G1 Phase - A period of normal metabolic activity – the number of cell organelles increases to normal levels and the volume of cytoplasm increases too, eventually reaching mature size. A cell can remain in this phase indefinitely.
II. S Phase - The DNA and chromosomes replicate. The cell is now committed to division.
III. G2 Phase - Structures directly involved with mitosis are formed. The new DNA is checked for errors and the substances that will be needed during mitosis are synthesized.
B. MITOSIS Mitosis is only the division of the nucleus into two identical nuclei. It is a continuous process, but has been artificially divided into 4 steps.
I. Prophase
II. Metaphase
III. Anaphase
IV. Telophase
I. Prophase
- The chromatin condenses into chromosomes by dehydrating and coiling. The chromosomes consist of two identical sister chromatids, joined together by a centromere. For the first time, they can be seen with alight microscope.
The nucleolus and nuclear envelope disappear, and the centriole (animal cells only) divides into two centrosomes, which move apart, creating the spindle.
II. Metaphase
The chromosomes are moved to the equator of the cell, and the centromeres are attached to the spindle fibers , so that the sister chromatids line up in the center of the cell.
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III. Anaphase
The centromeres of each chromosome divide and are pulled apart by the contraction of the spindle fibres, thus moving the chromosomes (as they must now be called) to opposite poles of the cell.
IV. Telophase
After the chromosomes reach the poles, the spindle disappears and the chromosomes return to their functional chromatin state by rehydrating and uncoiling.
A new nuclear envelope begins to form around the chromosomes at each end of the cell, each with its own nucleolus. With mitosis now over, cytokinesis can begin.
C. CYTOKINESIS
Following mitosis, cytokinesis completes the process of cell division. The cytoplasm divides by the pinching of the cell in the middle. The two cells formed are roughly equal in size.
Meiosis is a nuclear division that reduces the number of chromosomes in new
cells to half the original number (diploid, 2N → haploid, N). This counteracts the fusion of cells in fertilization (haploid, N → diploid, 2N).
Most organisms reproduce sexually, by the fusion of separate male (= sperm) and female (= egg or ovum) gametes. Eggs are much larger and non-motile; sperm are the smallest human cell and swim by means of a flagellum. Reproduction therefore depends on water.
Meiosis is the second type of nuclear division, but in this case the number of chromosomes is halved. As in mitosis, meiosis is followed by cytokinesis. It is otherwise very different:
I. Meiosis produces daughter cells with half the number of chromosomes of the parent cell, i.e. the cell goes from diploid to haploid.
II. Meiosis consists of two nuclear divisions, resulting in four haploid daughter cells.
III. The cells produced by meiosis are not all alike. Each cell is unique and this variation is produced by two processes – independent segregation of the chromosomes and by crossing-over. Both take place during Meiosis I.
STAGES OF MEIOSIS
Meiosis consists of two divisions:
A. During meiosis I homologous pairs of chromosomes are separated and cells become haploid.
B. During meiosis II the sister chromatids of each chromosome are separated (as in mitosis).
Meiosis I
At the start of meiosis, each chromosome consists of two sister chromatids, connected at the centromere. However, meiosis differs from mitosis, in that homologous pairs of chromosomes come together at the start of the meiosis, in a process called synapsis, forming a tetrad.
Prophase I.
1. Just as in mitosis, the nucleolus and nuclear membrane disappear, and the centriole divides and forms the spindle. As in mitosis, the chromosomes dehydrate and become thick and visible, but with the chromosomes of each homologous pair tangled together. There are thus four chromatids in each pair of chromosomes.
2. Portions of each chromatid may break off and reattach to an adjacent chromatid on the homologous chromosome. The places where this happens are called chiasma. The whole process is called crossing-over and it results in unique combination of alleles on each chromatid. Crossing-over can only take place between genes. This is an essential part of the genetic recombination that takes place in meiosis.
Metaphase I.
Homologous pairs are still together and arranged on the equator of the cell.
Anaphase I.
The homologous pairs of chromosomes separate from each other, as the spindle fibers pull one of each pair to opposite ends of the cell.
Telophase I.
Cytokinesis takes place; and each new cell is haploid, containing one chromosome from each pair.
MEIOSIS II 1. In males, this follows immediately. In females, meiosis I takes place
before birth, but meiosis II takes place only after the sperm has fused with the egg (i.e. immediately before fertilization).
The chromosomes do not replicate before this, second, division, so the gametes formed will have only half the DNA of a normal cell.
2. The second division of meiosis is essentially the same as mitosis. Often Telophase I is omitted and, after cell division, both daughter cells are already at the end of prophase II.
